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fix formatting problems that came about from incompatible tabbing in Lorenzo's patch

This commit is contained in:
Dick Hollenbeck 2011-12-05 01:03:57 -06:00
parent 40ee72653e
commit 680a4407f4
2 changed files with 297 additions and 275 deletions
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1
include/wxBasePcbFrame.h
View File

@ -80,7 +80,6 @@ public:
FOOTPRINT_EDIT_FRAME* m_ModuleEditFrame;
protected:
// EDA_RECT m_BoundaryBox; // Board size and position
BOARD* m_Pcb;
GENERAL_COLLECTOR* m_Collector;

571
pcbnew/export_gencad.cpp
View File

@ -47,7 +47,7 @@
static bool CreateHeaderInfoData( FILE* aFile, PCB_EDIT_FRAME* frame );
static void CreateArtworksSection( FILE* aFile);
static void CreateArtworksSection( FILE* aFile );
static void CreateTracksInfoData( FILE* aFile, BOARD* aPcb );
static void CreateBoardSection( FILE* aFile, BOARD* aPcb );
static void CreateComponentsSection( FILE* aFile, BOARD* aPcb );
@ -61,34 +61,34 @@ static void FootprintWriteShape( FILE* File, MODULE* module );
// layer name for Gencad export
static const wxString GenCADLayerName[32] =
{
wxT( "BOTTOM" ), wxT( "INNER1" ), wxT( "INNER2" ),
wxT( "INNER3" ), wxT( "INNER4" ), wxT( "INNER5" ),
wxT( "INNER6" ), wxT( "INNER7" ), wxT( "INNER8" ),
wxT( "INNER9" ), wxT( "INNER10" ), wxT( "INNER11" ),
wxT( "INNER12" ), wxT( "INNER13" ), wxT( "INNER14" ),
wxT( "TOP" ), wxT( "LAYER17" ), wxT( "LAYER18" ),
wxT( "BOTTOM" ), wxT( "INNER1" ), wxT( "INNER2" ),
wxT( "INNER3" ), wxT( "INNER4" ), wxT( "INNER5" ),
wxT( "INNER6" ), wxT( "INNER7" ), wxT( "INNER8" ),
wxT( "INNER9" ), wxT( "INNER10" ), wxT( "INNER11" ),
wxT( "INNER12" ), wxT( "INNER13" ), wxT( "INNER14" ),
wxT( "TOP" ), wxT( "LAYER17" ), wxT( "LAYER18" ),
wxT( "SOLDERPASTE_BOTTOM" ), wxT( "SOLDERPASTE_TOP" ),
wxT( "SILKSCREEN_BOTTOM" ), wxT( "SILKSCREEN_TOP" ),
wxT( "SOLDERMASK_BOTTOM" ), wxT( "SOLDERMASK_TOP" ), wxT( "LAYER25" ),
wxT( "LAYER26" ), wxT( "LAYER27" ), wxT( "LAYER28" ),
wxT( "LAYER29" ), wxT( "LAYER30" ), wxT( "LAYER31" ),
wxT( "SOLDERMASK_BOTTOM" ), wxT( "SOLDERMASK_TOP" ), wxT( "LAYER25" ),
wxT( "LAYER26" ), wxT( "LAYER27" ), wxT( "LAYER28" ),
wxT( "LAYER29" ), wxT( "LAYER30" ), wxT( "LAYER31" ),
wxT( "LAYER32" )
};
// flipped layer name for Gencad export (to make CAM350 imports correct)
static const wxString GenCADLayerNameFlipped[32] =
{
wxT( "TOP" ), wxT( "INNER14" ), wxT( "INNER13" ),
wxT( "INNER12" ), wxT( "INNER11" ), wxT( "INNER10" ),
wxT( "INNER9" ), wxT( "INNER8" ), wxT( "INNER7" ),
wxT( "INNER6" ), wxT( "INNER5" ), wxT( "INNER4" ),
wxT( "INNER3" ), wxT( "INNER2" ), wxT( "INNER1" ),
wxT( "BOTTOM" ), wxT( "LAYER17" ), wxT( "LAYER18" ),
wxT( "SOLDERPASTE_TOP" ), wxT( "SOLDERPASTE_BOTTOM" ),
wxT( "SILKSCREEN_TOP" ), wxT( "SILKSCREEN_BOTTOM" ),
wxT( "SOLDERMASK_TOP" ), wxT( "SOLDERMASK_BOTTOM" ), wxT( "LAYER25" ),
wxT( "LAYER26" ), wxT( "LAYER27" ), wxT( "LAYER28" ),
wxT( "LAYER29" ), wxT( "LAYER30" ), wxT( "LAYER31" ),
wxT( "TOP" ), wxT( "INNER14" ), wxT( "INNER13" ),
wxT( "INNER12" ), wxT( "INNER11" ), wxT( "INNER10" ),
wxT( "INNER9" ), wxT( "INNER8" ), wxT( "INNER7" ),
wxT( "INNER6" ), wxT( "INNER5" ), wxT( "INNER4" ),
wxT( "INNER3" ), wxT( "INNER2" ), wxT( "INNER1" ),
wxT( "BOTTOM" ), wxT( "LAYER17" ), wxT( "LAYER18" ),
wxT( "SOLDERPASTE_TOP" ), wxT( "SOLDERPASTE_BOTTOM" ),
wxT( "SILKSCREEN_TOP" ), wxT( "SILKSCREEN_BOTTOM" ),
wxT( "SOLDERMASK_TOP" ), wxT( "SOLDERMASK_BOTTOM" ), wxT( "LAYER25" ),
wxT( "LAYER26" ), wxT( "LAYER27" ), wxT( "LAYER28" ),
wxT( "LAYER29" ), wxT( "LAYER30" ), wxT( "LAYER31" ),
wxT( "LAYER32" )
};
@ -96,7 +96,7 @@ static const wxString GenCADLayerNameFlipped[32] =
static int GencadOffsetX, GencadOffsetY;
/* GerbTool chokes on units different than INCH so this is the conversion
factor */
* factor */
const static double SCALE_FACTOR = 10000.0;
@ -108,11 +108,13 @@ static double MapXTo( int aX )
return (aX - GencadOffsetX) / SCALE_FACTOR;
}
static double MapYTo( int aY )
{
return (GencadOffsetY - aY) / SCALE_FACTOR;
}
/* Driver function: processing starts here */
void PCB_EDIT_FRAME::ExportToGenCAD( wxCommandEvent& aEvent )
{
@ -155,7 +157,7 @@ void PCB_EDIT_FRAME::ExportToGenCAD( wxCommandEvent& aEvent )
* that are given as normal orientation (non flipped, rotation = 0))
* these changes will be undone later
*/
BOARD* pcb = GetBoard();
BOARD* pcb = GetBoard();
MODULE* module;
for( module = pcb->m_Modules; module != NULL; module = module->Next() )
@ -170,18 +172,18 @@ void PCB_EDIT_FRAME::ExportToGenCAD( wxCommandEvent& aEvent )
}
/* Gencad has some mandatory and some optional sections: some importer
need the padstack section (which is optional) anyway. Also the
order of the section *is* important */
* need the padstack section (which is optional) anyway. Also the
* order of the section *is* important */
CreateHeaderInfoData( file, this ); // Gencad header
CreateBoardSection( file, pcb ); // Board perimeter
CreateHeaderInfoData( file, this ); // Gencad header
CreateBoardSection( file, pcb ); // Board perimeter
CreatePadsShapesSection( file, pcb ); // Pads and padstacks
CreateArtworksSection( file ); // Empty but mandatory
CreatePadsShapesSection( file, pcb ); // Pads and padstacks
CreateArtworksSection( file ); // Empty but mandatory
/* Gencad splits a component info in shape, component and device.
We don't do any sharing (it would be difficult since each module is
customizable after placement) */
* We don't do any sharing (it would be difficult since each module is
* customizable after placement) */
CreateShapesSection( file, pcb );
CreateComponentsSection( file, pcb );
CreateDevicesSection( file, pcb );
@ -192,7 +194,7 @@ void PCB_EDIT_FRAME::ExportToGenCAD( wxCommandEvent& aEvent )
CreateRoutesSection( file, pcb );
fclose( file );
SetLocaleTo_Default(); // revert to the current locale
SetLocaleTo_Default(); // revert to the current locale
// Undo the footprints modifications (flipped footprints)
for( module = pcb->m_Modules; module != NULL; module = module->Next() )
@ -205,6 +207,7 @@ void PCB_EDIT_FRAME::ExportToGenCAD( wxCommandEvent& aEvent )
}
}
// Comparator for sorting pads with qsort
static int PadListSortByShape( const void* aRefptr, const void* aObjptr )
{
@ -214,24 +217,26 @@ static int PadListSortByShape( const void* aRefptr, const void* aObjptr )
return D_PAD::Compare( padref, padcmp );
}
// Sort vias for uniqueness
static int ViaSort(const void* aRefptr, const void* aObjptr )
static int ViaSort( const void* aRefptr, const void* aObjptr )
{
TRACK* padref = *(TRACK**)aRefptr;
TRACK* padcmp = *(TRACK**)aObjptr;
TRACK* padref = *(TRACK**) aRefptr;
TRACK* padcmp = *(TRACK**) aObjptr;
if( padref->m_Width != padcmp->m_Width )
return padref->m_Width-padcmp->m_Width;
return padref->m_Width - padcmp->m_Width;
if( padref->GetDrillValue() != padcmp->GetDrillValue() )
return padref->GetDrillValue()-padcmp->GetDrillValue();
return padref->GetDrillValue() - padcmp->GetDrillValue();
if( padref->ReturnMaskLayer() != padcmp->ReturnMaskLayer() )
return padref->ReturnMaskLayer()-padcmp->ReturnMaskLayer();
return padref->ReturnMaskLayer() - padcmp->ReturnMaskLayer();
return 0;
}
// The ARTWORKS section is empty but (officially) mandatory
static void CreateArtworksSection( FILE* aFile )
{
@ -240,6 +245,7 @@ static void CreateArtworksSection( FILE* aFile )
fputs( "$ENDARTWORKS\n\n", aFile );
}
// Emit PADS and PADSTACKS. They are sorted and emitted uniquely.
// Via name is synthesized from their attributes, pads are numbered
static void CreatePadsShapesSection( FILE* aFile, BOARD* aPcb )
@ -248,7 +254,7 @@ static void CreatePadsShapesSection( FILE* aFile, BOARD* aPcb )
std::vector<D_PAD*> padstacks;
std::vector<TRACK*> vias;
std::vector<TRACK*> viastacks;
padstacks.resize(1); // We count pads from 1
padstacks.resize( 1 ); // We count pads from 1
// The master layermask (i.e. the enabled layers) for padstack generation
unsigned master_layermask = aPcb->GetDesignSettings().GetEnabledLayers();
@ -259,37 +265,38 @@ static void CreatePadsShapesSection( FILE* aFile, BOARD* aPcb )
if( aPcb->GetPadsCount() > 0 )
{
pads.insert( pads.end(),
aPcb->m_NetInfo->m_PadsFullList.begin(),
aPcb->m_NetInfo->m_PadsFullList.end() );
aPcb->m_NetInfo->m_PadsFullList.begin(),
aPcb->m_NetInfo->m_PadsFullList.end() );
qsort( &pads[0], aPcb->GetPadsCount(), sizeof( D_PAD* ),
PadListSortByShape );
PadListSortByShape );
}
// The same for vias
for( TRACK* track = aPcb->m_Track; track != NULL; track = track->Next() )
{
if( track->Type() == PCB_VIA_T )
{
vias.push_back( track );
}
{
vias.push_back( track );
}
}
qsort( &vias[0], vias.size(), sizeof(TRACK*), ViaSort );
// Emit vias pads
TRACK* old_via = 0;
for( unsigned i = 0; i < vias.size(); i++ )
{
TRACK* via = vias[i];
if (old_via && 0 == ViaSort(&old_via, &via))
continue;
TRACK* via = vias[i];
if( old_via && 0 == ViaSort( &old_via, &via ) )
continue;
old_via = via;
viastacks.push_back(via);
fprintf( aFile, "PAD V%d.%d.%X ROUND %g\nCIRCLE 0 0 %g\n",
via->m_Width,via->GetDrillValue(),
via->ReturnMaskLayer(),
via->GetDrillValue()/SCALE_FACTOR,
via->m_Width/(SCALE_FACTOR*2) );
old_via = via;
viastacks.push_back( via );
fprintf( aFile, "PAD V%d.%d.%X ROUND %g\nCIRCLE 0 0 %g\n",
via->m_Width, via->GetDrillValue(),
via->ReturnMaskLayer(),
via->GetDrillValue() / SCALE_FACTOR,
via->m_Width / (SCALE_FACTOR * 2) );
}
// Emit component pads
@ -311,7 +318,7 @@ static void CreatePadsShapesSection( FILE* aFile, BOARD* aPcb )
fprintf( aFile, "PAD P%d", pad->GetSubRatsnest() );
padstacks.push_back(pad); // Will have its own padstack later
padstacks.push_back( pad ); // Will have its own padstack later
int dx = pad->m_Size.x / 2;
int dy = pad->m_Size.y / 2;
@ -320,101 +327,105 @@ static void CreatePadsShapesSection( FILE* aFile, BOARD* aPcb )
default:
case PAD_CIRCLE:
fprintf( aFile, " ROUND %g\n",
pad->m_Drill.x / SCALE_FACTOR );
/* Circle is center, radius */
pad->m_Drill.x / SCALE_FACTOR );
/* Circle is center, radius */
fprintf( aFile, "CIRCLE %g %g %g\n",
pad->m_Offset.x / SCALE_FACTOR,
-pad->m_Offset.y / SCALE_FACTOR,
pad->m_Size.x / (SCALE_FACTOR*2) );
pad->m_Offset.x / SCALE_FACTOR,
-pad->m_Offset.y / SCALE_FACTOR,
pad->m_Size.x / (SCALE_FACTOR * 2) );
break;
case PAD_RECT:
fprintf( aFile, " RECTANGULAR %g\n",
pad->m_Drill.x / SCALE_FACTOR );
// Rectangle is begin, size *not* begin, end!
pad->m_Drill.x / SCALE_FACTOR );
// Rectangle is begin, size *not* begin, end!
fprintf( aFile, "RECTANGLE %g %g %g %g\n",
(-dx + pad->m_Offset.x ) / SCALE_FACTOR,
(-dy - pad->m_Offset.y ) / SCALE_FACTOR,
dx / (SCALE_FACTOR/2) , dy / (SCALE_FACTOR/2) );
dx / (SCALE_FACTOR / 2), dy / (SCALE_FACTOR / 2) );
break;
case PAD_OVAL: // Create outline by 2 lines and 2 arcs
{
// OrCAD Layout call them OVAL or OBLONG - GenCAD call them FINGERs
// OrCAD Layout call them OVAL or OBLONG - GenCAD call them FINGERs
fprintf( aFile, " FINGER %g\n",
pad->m_Drill.x / SCALE_FACTOR );
pad->m_Drill.x / SCALE_FACTOR );
int dr = dx - dy;
if( dr >= 0 ) // Horizontal oval
{
int radius = dy;
fprintf( aFile, "LINE %g %g %g %g\n",
(-dr + pad->m_Offset.x) / SCALE_FACTOR,
(-pad->m_Offset.y - radius) / SCALE_FACTOR,
(dr + pad->m_Offset.x ) / SCALE_FACTOR,
(-pad->m_Offset.y - radius) / SCALE_FACTOR );
// GenCAD arcs are (start, end, center)
(-dr + pad->m_Offset.x) / SCALE_FACTOR,
(-pad->m_Offset.y - radius) / SCALE_FACTOR,
(dr + pad->m_Offset.x ) / SCALE_FACTOR,
(-pad->m_Offset.y - radius) / SCALE_FACTOR );
// GenCAD arcs are (start, end, center)
fprintf( aFile, "ARC %g %g %g %g %g %g\n",
(dr + pad->m_Offset.x) / SCALE_FACTOR,
(-pad->m_Offset.y - radius) / SCALE_FACTOR,
(dr + pad->m_Offset.x) / SCALE_FACTOR,
(-pad->m_Offset.y + radius) / SCALE_FACTOR,
(dr + pad->m_Offset.x) / SCALE_FACTOR,
-pad->m_Offset.y / SCALE_FACTOR );
(dr + pad->m_Offset.x) / SCALE_FACTOR,
(-pad->m_Offset.y - radius) / SCALE_FACTOR,
(dr + pad->m_Offset.x) / SCALE_FACTOR,
(-pad->m_Offset.y + radius) / SCALE_FACTOR,
(dr + pad->m_Offset.x) / SCALE_FACTOR,
-pad->m_Offset.y / SCALE_FACTOR );
fprintf( aFile, "LINE %g %g %g %g\n",
(dr + pad->m_Offset.x) / SCALE_FACTOR,
(-pad->m_Offset.y + radius) / SCALE_FACTOR,
(-dr + pad->m_Offset.x) / SCALE_FACTOR,
(-pad->m_Offset.y + radius) / SCALE_FACTOR );
(dr + pad->m_Offset.x) / SCALE_FACTOR,
(-pad->m_Offset.y + radius) / SCALE_FACTOR,
(-dr + pad->m_Offset.x) / SCALE_FACTOR,
(-pad->m_Offset.y + radius) / SCALE_FACTOR );
fprintf( aFile, "ARC %g %g %g %g %g %g\n",
(-dr + pad->m_Offset.x) / SCALE_FACTOR,
(-pad->m_Offset.y + radius) / SCALE_FACTOR,
(-dr + pad->m_Offset.x) / SCALE_FACTOR,
(-pad->m_Offset.y - radius) / SCALE_FACTOR,
(-dr + pad->m_Offset.x) / SCALE_FACTOR,
-pad->m_Offset.y / SCALE_FACTOR );
(-dr + pad->m_Offset.x) / SCALE_FACTOR,
(-pad->m_Offset.y + radius) / SCALE_FACTOR,
(-dr + pad->m_Offset.x) / SCALE_FACTOR,
(-pad->m_Offset.y - radius) / SCALE_FACTOR,
(-dr + pad->m_Offset.x) / SCALE_FACTOR,
-pad->m_Offset.y / SCALE_FACTOR );
}
else // Vertical oval
{
dr = -dr;
int radius = dx;
fprintf( aFile, "LINE %g %g %g %g\n",
(-radius + pad->m_Offset.x) / SCALE_FACTOR,
(-pad->m_Offset.y - dr) / SCALE_FACTOR,
(-radius + pad->m_Offset.x ) / SCALE_FACTOR,
(-pad->m_Offset.y + dr) / SCALE_FACTOR );
(-radius + pad->m_Offset.x) / SCALE_FACTOR,
(-pad->m_Offset.y - dr) / SCALE_FACTOR,
(-radius + pad->m_Offset.x ) / SCALE_FACTOR,
(-pad->m_Offset.y + dr) / SCALE_FACTOR );
fprintf( aFile, "ARC %g %g %g %g %g %g\n",
(-radius + pad->m_Offset.x ) / SCALE_FACTOR,
(-pad->m_Offset.y + dr) / SCALE_FACTOR,
(radius + pad->m_Offset.x ) / SCALE_FACTOR,
(-pad->m_Offset.y + dr) / SCALE_FACTOR,
pad->m_Offset.x / SCALE_FACTOR,
(-pad->m_Offset.y + dr) / SCALE_FACTOR );
(-radius + pad->m_Offset.x ) / SCALE_FACTOR,
(-pad->m_Offset.y + dr) / SCALE_FACTOR,
(radius + pad->m_Offset.x ) / SCALE_FACTOR,
(-pad->m_Offset.y + dr) / SCALE_FACTOR,
pad->m_Offset.x / SCALE_FACTOR,
(-pad->m_Offset.y + dr) / SCALE_FACTOR );
fprintf( aFile, "LINE %g %g %g %g\n",
(radius + pad->m_Offset.x) / SCALE_FACTOR,
(-pad->m_Offset.y + dr) / SCALE_FACTOR,
(radius + pad->m_Offset.x) / SCALE_FACTOR,
(-pad->m_Offset.y - dr) / SCALE_FACTOR );
(radius + pad->m_Offset.x) / SCALE_FACTOR,
(-pad->m_Offset.y + dr) / SCALE_FACTOR,
(radius + pad->m_Offset.x) / SCALE_FACTOR,
(-pad->m_Offset.y - dr) / SCALE_FACTOR );
fprintf( aFile, "ARC %g %g %g %g %g %g\n",
(radius + pad->m_Offset.x) / SCALE_FACTOR,
(-pad->m_Offset.y - dr) / SCALE_FACTOR,
(-pad->m_Offset.y - dr) / SCALE_FACTOR,
(-radius + pad->m_Offset.x) / SCALE_FACTOR,
(-pad->m_Offset.y - dr) / SCALE_FACTOR,
(-pad->m_Offset.y - dr) / SCALE_FACTOR,
pad->m_Offset.x / SCALE_FACTOR,
(-pad->m_Offset.y - dr) / SCALE_FACTOR );
(-pad->m_Offset.y - dr) / SCALE_FACTOR );
}
break;
}
case PAD_TRAPEZOID:
fprintf( aFile, " POLYGON %g\n",
pad->m_Drill.x / SCALE_FACTOR );
// XXX TO BE IMPLEMENTED! and I don't know if it could be actually imported by something
pad->m_Drill.x / SCALE_FACTOR );
// XXX TO BE IMPLEMENTED! and I don't know if it could be actually imported by something
break;
}
}
fputs( "\n$ENDPADS\n\n", aFile );
// Now emit the padstacks definitions, using the combined layer masks
@ -423,56 +434,58 @@ static void CreatePadsShapesSection( FILE* aFile, BOARD* aPcb )
// Via padstacks
for( unsigned i = 0; i < viastacks.size(); i++ )
{
TRACK *via = viastacks[i];
unsigned mask = via->ReturnMaskLayer() & master_layermask;
fprintf( aFile, "PADSTACK VIA%d.%d.%X %g\n",
via->m_Width, via->GetDrillValue(), mask,
via->GetDrillValue() / SCALE_FACTOR );
TRACK* via = viastacks[i];
unsigned mask = via->ReturnMaskLayer() & master_layermask;
fprintf( aFile, "PADSTACK VIA%d.%d.%X %g\n",
via->m_Width, via->GetDrillValue(), mask,
via->GetDrillValue() / SCALE_FACTOR );
for( int layer = 0; layer < 32; layer++)
{
if( mask & (1<<layer) )
for( int layer = 0; layer < 32; layer++ )
{
fprintf( aFile, "PAD V%d.%d.%X %s 0 0\n",
via->m_Width, via->GetDrillValue(),
mask,
TO_UTF8( GenCADLayerName[layer]) );
if( mask & (1 << layer) )
{
fprintf( aFile, "PAD V%d.%d.%X %s 0 0\n",
via->m_Width, via->GetDrillValue(),
mask,
TO_UTF8( GenCADLayerName[layer] ) );
}
}
}
}
/* Component padstacks
CAM350 don't apply correctly the FLIP semantics for padstacks, i.e. doesn't
swap the top and bottom layers... so I need to define the shape as MIRRORX
and define a separate 'flipped' padstack... until it appears yet another
noncompliant importer */
* CAM350 don't apply correctly the FLIP semantics for padstacks, i.e. doesn't
* swap the top and bottom layers... so I need to define the shape as MIRRORX
* and define a separate 'flipped' padstack... until it appears yet another
* noncompliant importer */
for( unsigned i = 1; i < padstacks.size(); i++ )
{
D_PAD *pad = padstacks[i];
D_PAD* pad = padstacks[i];
// Straight padstack
fprintf( aFile, "PADSTACK PAD%d %g\n", i,
pad->m_Drill.x / SCALE_FACTOR);
for( int layer = 0; layer < 32; layer++ )
{
if( pad->m_layerMask & (1<<layer) & master_layermask )
// Straight padstack
fprintf( aFile, "PADSTACK PAD%d %g\n", i,
pad->m_Drill.x / SCALE_FACTOR );
for( int layer = 0; layer < 32; layer++ )
{
fprintf( aFile, "PAD P%d %s 0 0\n", i,
TO_UTF8( GenCADLayerName[layer] ) );
if( pad->m_layerMask & (1 << layer) & master_layermask )
{
fprintf( aFile, "PAD P%d %s 0 0\n", i,
TO_UTF8( GenCADLayerName[layer] ) );
}
}
// Flipped padstack
fprintf( aFile, "PADSTACK PAD%dF %g\n", i,
pad->m_Drill.x / SCALE_FACTOR );
for( int layer = 0; layer < 32; layer++ )
{
if( pad->m_layerMask & (1 << layer) & master_layermask )
{
fprintf( aFile, "PAD P%d %s 0 0\n", i,
TO_UTF8( GenCADLayerNameFlipped[layer] ) );
}
}
}
// Flipped padstack
fprintf( aFile, "PADSTACK PAD%dF %g\n", i,
pad->m_Drill.x / SCALE_FACTOR);
for( int layer = 0; layer < 32; layer++ )
{
if( pad->m_layerMask & (1<<layer) & master_layermask )
{
fprintf( aFile, "PAD P%d %s 0 0\n", i,
TO_UTF8( GenCADLayerNameFlipped[layer] ) );
}
}
}
fputs( "$ENDPADSTACKS\n\n", aFile );
}
@ -498,20 +511,20 @@ static void CreateShapesSection( FILE* aFile, BOARD* aPcb )
for( pad = module->m_Pads; pad != NULL; pad = pad->Next() )
{
/* Funny thing: GenCAD requires the pad side even if you use
padstacks (which are theorically optional but gerbtools
*requires* them). Now the trouble thing is that 'BOTTOM'
is interpreted by someone as a padstack flip even
if the spec explicitly says it's not... */
/* Funny thing: GenCAD requires the pad side even if you use
* padstacks (which are theorically optional but gerbtools
*requires* them). Now the trouble thing is that 'BOTTOM'
* is interpreted by someone as a padstack flip even
* if the spec explicitly says it's not... */
layer = "ALL";
if( ( pad->m_layerMask & ALL_CU_LAYERS ) == LAYER_BACK )
{
layer = ( module->flag ) ? "TOP" : "BOTTOM";
layer = ( module->flag ) ? "TOP" : "BOTTOM";
}
else if( ( pad->m_layerMask & ALL_CU_LAYERS ) == LAYER_FRONT )
{
layer = ( module->flag ) ? "BOTTOM" : "TOP";
layer = ( module->flag ) ? "BOTTOM" : "TOP";
}
pad->ReturnStringPadName( pinname );
@ -522,20 +535,21 @@ static void CreateShapesSection( FILE* aFile, BOARD* aPcb )
orient = pad->m_Orient - module->m_Orient;
NORMALIZE_ANGLE_POS( orient );
// Bottom side modules use the flipped padstack
// Bottom side modules use the flipped padstack
fprintf( aFile, (module->flag) ?
"PIN %s PAD%dF %g %g %s %g %s\n" :
"PIN %s PAD%d %g %g %s %g %s\n",
TO_UTF8( pinname ), pad->GetSubRatsnest(),
pad->m_Pos0.x / SCALE_FACTOR,
-pad->m_Pos0.y / SCALE_FACTOR,
layer, orient / 10.0, mirror );
"PIN %s PAD%dF %g %g %s %g %s\n" :
"PIN %s PAD%d %g %g %s %g %s\n",
TO_UTF8( pinname ), pad->GetSubRatsnest(),
pad->m_Pos0.x / SCALE_FACTOR,
-pad->m_Pos0.y / SCALE_FACTOR,
layer, orient / 10.0, mirror );
}
}
fputs( "$ENDSHAPES\n\n", aFile );
}
/* Creates the section $COMPONENTS (Footprints placement)
* Bottom side components are difficult to handle: shapes must be mirrored or
* flipped, silk layers need to be handled correctly and so on. Also it seems
@ -543,15 +557,14 @@ static void CreateShapesSection( FILE* aFile, BOARD* aPcb )
*/
static void CreateComponentsSection( FILE* aFile, BOARD* aPcb )
{
fputs( "$COMPONENTS\n", aFile );
for(MODULE* module = aPcb->m_Modules ; module != NULL; module = module->Next() )
for( MODULE* module = aPcb->m_Modules; module != NULL; module = module->Next() )
{
TEXTE_MODULE* textmod;
const char* mirror;
const char* flip;
int orient = module->m_Orient;
TEXTE_MODULE* textmod;
const char* mirror;
const char* flip;
int orient = module->m_Orient;
if( module->flag )
{
@ -566,20 +579,20 @@ static void CreateComponentsSection( FILE* aFile, BOARD* aPcb )
}
fprintf( aFile, "\nCOMPONENT %s\n",
TO_UTF8( module->m_Reference->m_Text ) );
TO_UTF8( module->m_Reference->m_Text ) );
fprintf( aFile, "DEVICE %s_%s\n",
TO_UTF8( module->m_Reference->m_Text ),
TO_UTF8( module->m_Value->m_Text ) );
TO_UTF8( module->m_Reference->m_Text ),
TO_UTF8( module->m_Value->m_Text ) );
fprintf( aFile, "PLACE %g %g\n",
MapXTo( module->m_Pos.x ),
MapYTo( module->m_Pos.y ) );
MapXTo( module->m_Pos.x ),
MapYTo( module->m_Pos.y ) );
fprintf( aFile, "LAYER %s\n",
(module->flag) ? "BOTTOM" : "TOP" );
(module->flag) ? "BOTTOM" : "TOP" );
fprintf( aFile, "ROTATION %g\n",
orient / 10.0 );
orient / 10.0 );
fprintf( aFile, "SHAPE %s %s %s\n",
TO_UTF8( module->m_Reference->m_Text ),
mirror, flip );
TO_UTF8( module->m_Reference->m_Text ),
mirror, flip );
// Text on silk layer: RefDes and value (are they actually useful?)
textmod = module->m_Reference;
@ -588,21 +601,21 @@ static void CreateComponentsSection( FILE* aFile, BOARD* aPcb )
{
int orient = textmod->m_Orient;
wxString layer = GenCADLayerName[(module->flag) ?
SILKSCREEN_N_BACK : SILKSCREEN_N_FRONT];
SILKSCREEN_N_BACK : SILKSCREEN_N_FRONT];
fprintf( aFile, "TEXT %g %g %g %g %s %s \"%s\"",
textmod->m_Pos0.x / SCALE_FACTOR,
-textmod->m_Pos0.y / SCALE_FACTOR,
textmod->m_Size.x / SCALE_FACTOR,
orient / 10.0,
mirror,
TO_UTF8( layer ),
TO_UTF8( textmod->m_Text ) );
textmod->m_Pos0.x / SCALE_FACTOR,
-textmod->m_Pos0.y / SCALE_FACTOR,
textmod->m_Size.x / SCALE_FACTOR,
orient / 10.0,
mirror,
TO_UTF8( layer ),
TO_UTF8( textmod->m_Text ) );
// Please note, the width is approx
// Please note, the width is approx
fprintf( aFile, " 0 0 %g %g\n",
(textmod->m_Size.x * textmod->m_Text.Len())
/ SCALE_FACTOR,
( textmod->m_Size.x * textmod->m_Text.Len() )
/ SCALE_FACTOR,
textmod->m_Size.y / SCALE_FACTOR );
textmod = module->m_Value; // Dirty trick for the second iteration
@ -610,13 +623,14 @@ static void CreateComponentsSection( FILE* aFile, BOARD* aPcb )
// The SHEET is a 'generic description' for referencing the component
fprintf( aFile, "SHEET \"RefDes: %s, Value: %s\"\n",
TO_UTF8( module->m_Reference->m_Text ),
TO_UTF8( module->m_Value->m_Text ) );
TO_UTF8( module->m_Reference->m_Text ),
TO_UTF8( module->m_Value->m_Text ) );
}
fputs( "$ENDCOMPONENTS\n\n", aFile );
}
/* Emit the netlist (which is actually the thing for which GenCAD is used these
* days!); tracks are handled later */
static void CreateSignalsSection( FILE* aFile, BOARD* aPcb )
@ -658,8 +672,8 @@ static void CreateSignalsSection( FILE* aFile, BOARD* aPcb )
pad->ReturnStringPadName( padname );
msg.Printf( wxT( "NODE %s %s" ),
GetChars( module->m_Reference->m_Text ),
GetChars( padname ) );
GetChars( module->m_Reference->m_Text ),
GetChars( padname ) );
fputs( TO_UTF8( msg ), aFile );
fputs( "\n", aFile );
@ -683,18 +697,18 @@ static bool CreateHeaderInfoData( FILE* aFile, PCB_EDIT_FRAME* aFrame )
// Please note: GenCAD syntax requires quoted strings if they can contain spaces
msg.Printf( wxT( "USER \"%s %s\"\n" ),
GetChars( wxGetApp().GetAppName() ),
GetChars( GetBuildVersion() ) );
GetChars( wxGetApp().GetAppName() ),
GetChars( GetBuildVersion() ) );
fputs( TO_UTF8( msg ), aFile );
msg = wxT( "DRAWING \"" ) + screen->GetFileName() + wxT( "\"\n" );
fputs( TO_UTF8( msg ), aFile );
msg = wxT( "REVISION \"" ) + screen->m_Revision + wxT( " " ) +
screen->m_Date + wxT( "\"\n" );
screen->m_Date + wxT( "\"\n" );
fputs( TO_UTF8( msg ), aFile );
fputs( "UNITS INCH\n", aFile);
fputs( "UNITS INCH\n", aFile );
msg.Printf( wxT( "ORIGIN %g %g\n" ),
MapXTo( aFrame->m_Auxiliary_Axis_Position.x ),
MapYTo( aFrame->m_Auxiliary_Axis_Position.y ) );
MapXTo( aFrame->m_Auxiliary_Axis_Position.x ),
MapYTo( aFrame->m_Auxiliary_Axis_Position.y ) );
fputs( TO_UTF8( msg ), aFile );
fputs( "INTERTRACK 0\n", aFile );
fputs( "$ENDHEADER\n\n", aFile );
@ -702,6 +716,7 @@ static bool CreateHeaderInfoData( FILE* aFile, PCB_EDIT_FRAME* aFrame )
return true;
}
/*
* Sort function used to sort tracks segments:
* items are sorted by netcode, then by width then by layer
@ -738,10 +753,10 @@ static int TrackListSortByNetcode( const void* refptr, const void* objptr )
*/
static void CreateRoutesSection( FILE* aFile, BOARD* aPcb )
{
TRACK* track, ** tracklist;
int vianum = 1;
int old_netcode, old_width, old_layer;
int nbitems, ii;
TRACK* track, ** tracklist;
int vianum = 1;
int old_netcode, old_width, old_layer;
int nbitems, ii;
unsigned master_layermask = aPcb->GetDesignSettings().GetEnabledLayers();
// Count items
@ -756,7 +771,7 @@ static void CreateRoutesSection( FILE* aFile, BOARD* aPcb )
nbitems++;
}
tracklist = (TRACK**) operator new( (nbitems + 1) * sizeof( TRACK* ) );
tracklist = (TRACK**) operator new( (nbitems + 1)* sizeof( TRACK* ) );
nbitems = 0;
@ -807,20 +822,20 @@ static void CreateRoutesSection( FILE* aFile, BOARD* aPcb )
{
old_layer = track->GetLayer();
fprintf( aFile, "LAYER %s\n",
TO_UTF8( GenCADLayerName[track->GetLayer() & 0x1F] ) );
TO_UTF8( GenCADLayerName[track->GetLayer() & 0x1F] ) );
}
fprintf( aFile, "LINE %g %g %g %g\n",
MapXTo( track->m_Start.x ), MapYTo( track->m_Start.y ),
MapXTo( track->m_End.x ), MapYTo( track->m_End.y ) );
MapXTo( track->m_Start.x ), MapYTo( track->m_Start.y ),
MapXTo( track->m_End.x ), MapYTo( track->m_End.y ) );
}
if( track->Type() == PCB_VIA_T )
{
fprintf( aFile, "VIA VIA%d.%d.%X %g %g ALL %g via%d\n",
track->m_Width,track->GetDrillValue(),
track->m_Width, track->GetDrillValue(),
track->ReturnMaskLayer() & master_layermask,
MapXTo( track->m_Start.x ), MapYTo( track->m_Start.y ),
track->GetDrillValue()/SCALE_FACTOR, vianum++ );
track->GetDrillValue() / SCALE_FACTOR, vianum++ );
}
}
@ -841,12 +856,13 @@ static void CreateDevicesSection( FILE* aFile, BOARD* aPcb )
fputs( "$DEVICES\n", aFile );
for( module = aPcb->m_Modules; module != NULL; module = module->Next() )
{
{
fprintf( aFile, "DEVICE \"%s\"\n", TO_UTF8( module->m_Reference->m_Text ) );
fprintf( aFile, "PART \"%s\"\n", TO_UTF8( module->m_Value->m_Text ) );
fprintf( aFile, "PACKAGE \"%s\"\n", TO_UTF8( module->m_LibRef ) );
// The TYPE attribute is almost freeform
const char *ty = "TH";
fprintf( aFile, "PACKAGE \"%s\"\n", TO_UTF8( module->m_LibRef ) );
// The TYPE attribute is almost freeform
const char* ty = "TH";
if( module->m_Attributs & MOD_CMS )
ty = "SMD";
if( module->m_Attributs & MOD_VIRTUAL )
@ -864,23 +880,25 @@ static void CreateDevicesSection( FILE* aFile, BOARD* aPcb )
static void CreateBoardSection( FILE* aFile, BOARD* aPcb )
{
fputs( "$BOARD\n", aFile );
// Extract the board edges
for (EDA_ITEM* drawing = aPcb->m_Drawings;
for( EDA_ITEM* drawing = aPcb->m_Drawings;
drawing != 0;
drawing = drawing->Next() )
{
if ( drawing->Type() == PCB_LINE_T )
{
DRAWSEGMENT *drawseg = dynamic_cast<DRAWSEGMENT*>(drawing);
if (drawseg->GetLayer() == EDGE_N)
if( drawing->Type() == PCB_LINE_T )
{
// XXX GenCAD supports arc boundaries but I've seen nothing that reads them
fprintf( aFile, "LINE %g %g %g %g\n",
MapXTo(drawseg->m_Start.x), MapYTo(drawseg->m_Start.y),
MapXTo(drawseg->m_End.x), MapYTo(drawseg->m_End.y));
DRAWSEGMENT* drawseg = dynamic_cast<DRAWSEGMENT*>( drawing );
if( drawseg->GetLayer() == EDGE_N )
{
// XXX GenCAD supports arc boundaries but I've seen nothing that reads them
fprintf( aFile, "LINE %g %g %g %g\n",
MapXTo( drawseg->m_Start.x ), MapYTo( drawseg->m_Start.y ),
MapXTo( drawseg->m_End.x ), MapYTo( drawseg->m_End.y ) );
}
}
}
}
fputs( "$ENDBOARD\n\n", aFile );
}
@ -947,7 +965,7 @@ static void CreateTracksInfoData( FILE* aFile, BOARD* aPcb )
for( ii = 0; ii < trackinfo.size(); ii++ )
{
fprintf( aFile, "TRACK TRACK%d %g\n", trackinfo[ii],
trackinfo[ii] / SCALE_FACTOR );
trackinfo[ii] / SCALE_FACTOR );
}
fputs( "$ENDTRACKS\n\n", aFile );
@ -961,10 +979,11 @@ static void CreateTracksInfoData( FILE* aFile, BOARD* aPcb )
*/
static void FootprintWriteShape( FILE* aFile, MODULE* module )
{
EDGE_MODULE* PtEdge;
EDA_ITEM* PtStruct;
EDGE_MODULE* PtEdge;
EDA_ITEM* PtStruct;
// Control Y axis change sign for flipped modules
int Yaxis_sign = -1;
int Yaxis_sign = -1;
// Flip for bottom side components
if( module->flag )
@ -975,13 +994,13 @@ static void FootprintWriteShape( FILE* aFile, MODULE* module )
if( module->m_Attributs & MOD_VIRTUAL )
{
fprintf( aFile, "INSERT SMD\n");
fprintf( aFile, "INSERT SMD\n" );
}
else
{
if( module->m_Attributs & MOD_CMS )
{
fprintf( aFile, "INSERT SMD\n");
{
fprintf( aFile, "INSERT SMD\n" );
}
else
{
@ -1015,68 +1034,72 @@ static void FootprintWriteShape( FILE* aFile, MODULE* module )
switch( PtStruct->Type() )
{
case PCB_MODULE_TEXT_T:
// If we wanted to export text, this is not the correct section
// If we wanted to export text, this is not the correct section
break;
case PCB_MODULE_EDGE_T:
PtEdge = (EDGE_MODULE*) PtStruct;
if( PtEdge->GetLayer() == SILKSCREEN_N_FRONT
|| PtEdge->GetLayer() == SILKSCREEN_N_BACK )
|| PtEdge->GetLayer() == SILKSCREEN_N_BACK )
{
switch( PtEdge->m_Shape )
{
case S_SEGMENT:
{
case S_SEGMENT:
fprintf( aFile, "LINE %g %g %g %g\n",
(PtEdge->m_Start0.x) / SCALE_FACTOR,
(Yaxis_sign * PtEdge->m_Start0.y) / SCALE_FACTOR,
(PtEdge->m_End0.x) / SCALE_FACTOR,
(Yaxis_sign * PtEdge->m_End0.y ) / SCALE_FACTOR);
break;
(PtEdge->m_Start0.x) / SCALE_FACTOR,
(Yaxis_sign * PtEdge->m_Start0.y) / SCALE_FACTOR,
(PtEdge->m_End0.x) / SCALE_FACTOR,
(Yaxis_sign * PtEdge->m_End0.y ) / SCALE_FACTOR );
break;
case S_CIRCLE:
{
int radius = (int) hypot(
(double) ( PtEdge->m_End0.x - PtEdge->m_Start0.x ),
(double) ( PtEdge->m_End0.y - PtEdge->m_Start0.y ) );
fprintf( aFile, "CIRCLE %g %g %g\n",
PtEdge->m_Start0.x / SCALE_FACTOR,
Yaxis_sign * PtEdge->m_Start0.y / SCALE_FACTOR,
radius / SCALE_FACTOR );
break;
}
case S_CIRCLE:
{
int radius = (int) hypot(
(double) ( PtEdge->m_End0.x - PtEdge->m_Start0.x ),
(double) ( PtEdge->m_End0.y - PtEdge->m_Start0.y ) );
fprintf( aFile, "CIRCLE %g %g %g\n",
PtEdge->m_Start0.x / SCALE_FACTOR,
Yaxis_sign * PtEdge->m_Start0.y / SCALE_FACTOR,
radius / SCALE_FACTOR );
break;
}
case S_ARC:
{
int arcendx, arcendy;
arcendx = PtEdge->m_End0.x - PtEdge->m_Start0.x;
arcendy = PtEdge->m_End0.y - PtEdge->m_Start0.y;
RotatePoint( &arcendx, &arcendy, -PtEdge->m_Angle );
arcendx += PtEdge->m_Start0.x;
arcendy += PtEdge->m_Start0.y;
if( Yaxis_sign == -1 )
{
int arcendx, arcendy;
arcendx = PtEdge->m_End0.x - PtEdge->m_Start0.x;
arcendy = PtEdge->m_End0.y - PtEdge->m_Start0.y;
RotatePoint( &arcendx, &arcendy, -PtEdge->m_Angle );
arcendx += PtEdge->m_Start0.x;
arcendy += PtEdge->m_Start0.y;
if (Yaxis_sign == -1) {
// Flipping Y flips the arc direction too
fprintf( aFile, "ARC %g %g %g %g %g %g\n",
(arcendx) / SCALE_FACTOR,
(Yaxis_sign * arcendy) / SCALE_FACTOR,
(PtEdge->m_End0.x) / SCALE_FACTOR,
(Yaxis_sign * PtEdge->m_End0.y) / SCALE_FACTOR,
(PtEdge->m_Start0.x) / SCALE_FACTOR,
(Yaxis_sign * PtEdge->m_Start0.y) / SCALE_FACTOR );
} else {
fprintf( aFile, "ARC %g %g %g %g %g %g\n",
(PtEdge->m_End0.x) / SCALE_FACTOR,
(Yaxis_sign * PtEdge->m_End0.y) / SCALE_FACTOR,
(arcendx) / SCALE_FACTOR,
(Yaxis_sign * arcendy) / SCALE_FACTOR,
(PtEdge->m_Start0.x) / SCALE_FACTOR,
(Yaxis_sign * PtEdge->m_Start0.y) / SCALE_FACTOR );
}
break;
}
// Flipping Y flips the arc direction too
fprintf( aFile, "ARC %g %g %g %g %g %g\n",
(arcendx) / SCALE_FACTOR,
(Yaxis_sign * arcendy) / SCALE_FACTOR,
(PtEdge->m_End0.x) / SCALE_FACTOR,
(Yaxis_sign * PtEdge->m_End0.y) / SCALE_FACTOR,
(PtEdge->m_Start0.x) / SCALE_FACTOR,
(Yaxis_sign * PtEdge->m_Start0.y) / SCALE_FACTOR );
}
else
{
fprintf( aFile, "ARC %g %g %g %g %g %g\n",
(PtEdge->m_End0.x) / SCALE_FACTOR,
(Yaxis_sign * PtEdge->m_End0.y) / SCALE_FACTOR,
(arcendx) / SCALE_FACTOR,
(Yaxis_sign * arcendy) / SCALE_FACTOR,
(PtEdge->m_Start0.x) / SCALE_FACTOR,
(Yaxis_sign * PtEdge->m_Start0.y) / SCALE_FACTOR );
}
break;
}
default:
DisplayError( NULL, wxT( "Type Edge Module invalid." ) );
break;
default:
DisplayError( NULL, wxT( "Type Edge Module invalid." ) );
break;
}
}
break;